Vertical mouse

ABSTRACT

A vertical mouse includes a base and a mouse body. The base has a vertical receiving groove. The mouse body includes a housing. The mouse body is detachably received in the vertical receiving groove, the housing leans against the vertical receiving groove, and the mouse body has a first operation mode and a second operation mode. Under the first operation mode, the mouse body is received in the base with a first orientation, and under the second operation mode, the mouse body is received in the base with a second orientation.

CROSS-REFERENCE TO RELATED APPLICATION

This non-provisional application claims priority under 35 U.S.C. §119(a) to Patent Application No. 111123299 filed in Taiwan, R.O.C. onJun. 22, 2022, the entire contents of which are hereby incorporated byreference.

BACKGROUND Technical Field

The instant disclosure relates to input devices for electronic devices,in particular, to a vertical mouse.

Related Art

Vertical mice are electronic input devices for reducing burden on user'shands. A main purpose of the vertical mice is to allow the user's palmto hold the mouse vertically by configuring the appearance of thevertical mouse ergonomically.

Most users operate the mice with their right hands. Thus, mostmanufacturers produce vertical mice suitable for right-handed users. Asa result, in general, vertical mice suitable for left-handed userscannot be obtained easily, and the user may obtain a vertical mouse forleft-handed users through customized processes. Consequently, themarket-available products are not friendly for the users who areleft-handed users and who use the vertical mice.

SUMMARY

In view of this, according to some embodiments, a vertical mouse isprovided. The vertical mouse comprises a base and a mouse body. The basehas a vertical receiving groove. The mouse body comprises a housing, themouse body is detachably received in the vertical receiving groove, thehousing leans against the vertical receiving groove, and the mouse bodyhas a first operation mode and a second operation mode. Under the firstoperation mode, the mouse body is received in the base with a firstorientation, and under the second operation mode, the mouse body isreceived in the base with a second orientation.

According to some embodiments, the user can place the vertical mouse onan operating surface and operates the vertical mouse, with the palm ofthe user placed standingly, thus reducing the pressure applied to theuser's wrist during the operation of the vertical mouse. Moreover,according to some embodiments, the user just needs to rotate the baseand the mouse body respectively to allow the vertical mouse to besuitable for right-handed users or left-handed users. Therefore,according to some embodiments, the same vertical mouse is suitable forboth the right-handed users and left-handed users, and the verticalmouse thus provides a great convenience for the users.

In some embodiments, a back surface of the housing of the mouse body issymmetrically arranged along a first symmetry axis and is symmetricallyarranged along a second symmetry axis perpendicular to the firstsymmetry axis, a side surface of the housing is arranged along a profileof the back surface, and the back surface and the side surfacerespectively lean against the vertical receiving groove.

In some embodiments, the first symmetry axis and the second symmetryaxis are intersected at a symmetry center, the mouse body is selectivelyreceived in the vertical receiving groove with one of a plurality oforientations, and the mouse body is rotated about the symmetry center,so that the mouse body is arranged with multiple orientations.

In some embodiments, the vertical receiving groove of the base furtherhas a first positioning portion, a back surface of the mouse bodyfurther has a second positioning portion, and the mouse body is slidablyfitted over the first positioning portion through the second positioningportion.

In some embodiments, the base further comprises a first magneticattractive member, and the mouse body further comprises a secondmagnetic attractive member and a third magnetic attractive member. Whenthe mouse body is received in the vertical receiving groove with thefirst orientation, the first magnetic attractive member is magneticallyattracted to the second magnetic attractive member. When the mouse bodyis received in the vertical receiving groove with the secondorientation, the first magnetic attractive member is magneticallyattracted to the third magnetic attractive member.

In some embodiments, a back surface of the housing of the mouse body isarranged along a first symmetry axis, and the third magnetic attractivemember and the second magnetic attractive member are at opposite sideswith respect to the first symmetry axis.

In some embodiments, the symmetry center of the mouse body iscorrespondingly in the vertical receiving groove of the base.

In some embodiments, the vertical receiving groove has a first leaningsurface, an angle is between an extension direction of the first leaningsurface and a bottom surface of the base, and a back surface of themouse body is attached to the first leaning surface.

In some embodiments, the angle is in a range between 50 degrees and 70degrees.

According to some embodiments, a vertical mouse is provided. Thevertical mouse is adapted to be utilized along with an electronicdevice. The vertical mouse comprises a base, a mouse body, and aswitching module. The base is communicatively connected to theelectronic device. The base comprises a first sensing module and a firstcommunication module, and the first sensing module is configured todetect a movement of the base. The mouse body comprises an operatingstructure and a second communication unit. The operating structure isconfigured to control the electronic device, the second communicationunit is communicatively connected to the first communication unit, themouse body is detachably arranged on the base, and the mouse body has afirst operation mode and a second operation mode. Under the firstoperation mode, the mouse body is arranged on the base with a firstorientation, and under the second operation mode, the mouse body isarranged on the base with a second orientation. The switching module iscommunicatively connected to the operating structure. The switchingmodule is configured to switch the operating structure to correspond tothe first operation mode or the second operation mode.

In some embodiments, when the mouse body is arranged on the base and thebase is moving, the first sensing module of the base generates amovement signal, and the base transmits the movement signal to theelectronic device.

In some embodiments, when the mouse body is arranged on the base andcontrols the operating structure of the mouse body, the operatingstructure generates a control signal and transmits the control signal tothe base through the second communication unit, and the base transmitsthe control signal to the electronic device to control the electronicdevice.

In some embodiments, the operating structure comprises two operatingbuttons. When an orientation of the mouse body is changed, the switchingmodule switches functions of the two operating buttons.

In some embodiments, the switching module comprises a switching circuitand a sensor electrically connected to the switching circuit, and theswitching circuit detects whether the mouse body is under the firstoperation mode or the second operation mode according to the sensor soas to switch functions of the operating structure.

In some embodiments, the base further comprises two sensing portions.Under the first operation mode, a position of the sensor corresponds toa position of one of the two sensing portions. Under the secondoperation mode, the position of the sensor corresponds to a position ofthe other sensing portion. When the sensing portion sensed by the sensoris changed, the switching circuit switches the function of the operatingstructure.

In some embodiments, the sensor is a Hall sensor, and the sensingportions are magnets.

In some embodiments, the sensor is a G-sensor to detect whether themouse body is under the first operation mode, the second operation mode,or operating on an operating surface alone.

In some embodiments, the first communication unit and the secondcommunication unit are communicatively connected to each other in acontact type manner.

In some embodiments, the first communication unit comprises a firstconnector, the second communication unit comprises a second connector,and the first connector contacts the second connector, so that the firstcommunication unit and the second communication unit are communicativelyconnected to each other.

In some embodiments, the first connector is a pogo pin connector, andthe second connector is a conductive contact.

According to some embodiments, a vertical mouse is provided. Thevertical mouse is adapted to be utilized along with an electronicdevice. The vertical mouse comprises a base, a mouse body, and aswitching module. The base is communicatively connected to theelectronic device. The base comprises a first sensing module and a firstcommunication unit, and the first sensing module is configured to detecta movement of the base. The mouse body comprises an operating structure,a second communication unit, and a second wireless communication unit.The operating structure is configured to control the electronic device,the second communication unit is communicatively connected to the firstcommunication unit, the second wireless communication unit is wirelesslycommunicatively connected to the electronic device, the mouse body isdetachably arranged on the base, and the mouse body has a firstoperation mode and a second operation mode. Under the first operationmode, the mouse body is arranged on the base with a first orientation,and under the second operation mode, the mouse body is arranged on thebase with a second orientation. The switching module is communicativelyconnected to the operating structure. The switching module is configuredto switch the operating structure to correspond to the first operationmode or the second operation mode.

In some embodiments, the switching module comprises a switching circuitand a switching structure electrically connected to the switchingcircuit, and the switching circuit switches functions of the operatingstructure according to a triggering of the switching structure.

In some embodiments, the mouse body comprises a second sensing moduleand a power unit, and the second sensing module is configured to detecta movement of the mouse body. When the mouse body is detached from thebase and is moving, the second sensing module of the mouse bodygenerates a movement signal, and the second wireless communication unittransmits the movement signal to the electronic device.

In some embodiments, when the mouse body is detached from the base andcontrols the operating structure of the mouse body, the operatingstructure generates a control signal and transmits the control signal tothe electronic device through the second wireless communication unit tocontrol the electronic device.

In some embodiments, the first communication unit and the secondcommunication unit are corresponding noncontact type communicationstructures.

In some embodiments, the base further comprises a first wirelesscommunication unit, and the base is wirelessly communicatively connectedto the electronic device through the first wireless communication unit.

In some embodiments, when the mouse body is arranged on the base and thebase is moving, the first sensing module of the base generates amovement signal, and the first wireless communication unit transmits themovement signal to the electronic device.

In some embodiments, when the mouse body is arranged on the base andcontrols the operating structure of the mouse body, the operatingstructure generates a control signal and transmits the control signal tothe base through the second communication unit, and the base transmitsthe control signal to the electronic device through the first wirelesscommunication unit to control the electronic device.

According to some embodiments, a vertical mouse is provided. Thevertical mouse is adapted to be utilized along with an electronic deviceand an external device. The vertical mouse comprises a base, a mousebody, and a switching module. The base is communicatively connected tothe external device. The base comprises a first sensing module and afirst communication unit, and the first sensing module is configured todetect a movement of the base. The mouse body comprises an operatingstructure, a second communication unit, and a second wirelesscommunication unit. The operating structure is configured to control theelectronic device, the second communication unit is communicativelyconnected to the first communication unit, the second wirelesscommunication unit is wirelessly communicatively connected to theelectronic device, the mouse body is detachably arranged on the base,and the mouse body has a first operation mode and a second operationmode. Under the first operation mode, the mouse body is arranged on thebase with a first orientation, and under the second operation mode, themouse body is arranged on the base with a second orientation. Theswitching module is communicatively connected to the operatingstructure. The switching module is configured to switch the operatingstructure to correspond to the first operation mode or the secondoperation mode.

In some embodiments, when the mouse body is arranged on the base and thebase is moving, the first sensing module of the base generates amovement signal, the first communication unit transmits the movementsignal to the second communication unit of the mouse body, and thesecond wireless communication unit of the mouse body transmits themovement signal to the electronic device.

In some embodiments, when the mouse body is arranged on the base andcontrols the operating structure of the mouse body, the operatingstructure generates a control signal and transmits the control signal tothe electronic device through the second wireless communication unit tocontrol the electronic device.

In some embodiments, the switching module comprises a switching circuitand a sensor electrically connected to the switching circuit, and theswitching circuit detects whether the mouse body is under the firstoperation mode or the second operation mode according to the sensor soas to switch functions of the operating structure.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosure will become more fully understood from the detaileddescription given herein below for illustration only, and thus notlimitative of the disclosure, wherein:

FIG. 1 illustrates an exploded view of a vertical mouse according to anexemplary embodiment of the instant disclosure, which shows that thebase and the mouse body are communicatively connected to each other in acontact type manner;

FIG. 2 illustrates a systematic block diagram of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the base and the mouse body are communicatively connected toeach other in a contact type manner;

FIG. 3 illustrates a lateral view of a vertical mouse according to anexemplary embodiment of the instant disclosure, which shows that themouse body is under the first operation mode;

FIG. 4 illustrates a lateral view of a vertical mouse according to anexemplary embodiment of the instant disclosure, which shows that themouse body is under the second operation mode;

FIG. 5 illustrates a schematic operational view of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the mouse body is under the first operation mode;

FIG. 6 illustrates a schematic operational view of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the mouse body is under the second operation mode;

FIG. 7 illustrates a perspective view of a vertical mouse according toan exemplary embodiment of the instant disclosure, which shows that thebase is detached from the mouse body;

FIG. 8 illustrates a cross-sectional view of a vertical mouse accordingto an exemplary embodiment of the instant disclosure;

FIG. 9 illustrates a bottom view of a vertical mouse according to anexemplary embodiment of the instant disclosure;

FIG. 10 illustrates a bottom view of a vertical mouse according toanother exemplary embodiment of the instant disclosure;

FIG. 11 illustrates an exploded view of a vertical mouse according to anexemplary embodiment of the instant disclosure, which shows that thebase and the mouse body are positioned with each other through the firstpositioning portion and the second positioning portion;

FIG. 12 illustrates a systematic block diagram of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows the functions of the operating buttons are manually switchedaccording to the switching structure;

FIG. 13 illustrates a systematic block diagram of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the base is connected to the external device and the mousebody switches the functions of the operating buttons according to thesensing of the sensor; and

FIG. 14 illustrates a systematic block diagram of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the base is provided with a first wireless communication unitand the mouse body is provided with a second wireless communicationunit.

DETAILED DESCRIPTION

With reference to FIG. 1 and FIG. 2 . FIG. 1 illustrates an explodedview of a vertical mouse according to an exemplary embodiment of theinstant disclosure, which shows that the base 10 and the mouse body 20are communicatively connected to each other in a contact type manner.FIG. 2 illustrates a systematic block diagram of a vertical mouseaccording to an exemplary embodiment of the instant disclosure, whichshows that the base 10 and the mouse body 20 are communicativelyconnected to each other in a contact type manner. The vertical mouse isan input device of an electronic device, and the vertical mouse isconfigured to control the operation of the electronic device (e.g., tomove the cursor, to scroll the page, or to switch the menus). In someembodiments, the vertical mouse comprises a base 10 and a mouse body 20.The base 10 comprises a case 11 and a vertical receiving groove 112. Themouse body 20 comprises a housing 21, the mouse body 20 is detachablyreceived in the vertical receiving groove 112, the housing 21 leansagainst the vertical receiving groove 112, and the mouse body 20 has afirst operation mode and a second operation mode. Under the firstoperation mode, the mouse body 20 is received in the base 10 with afirst orientation (as shown in FIG. 3 ), and under the second operationmode, the mouse body 20 is detached from the base 10 with the firstorientation and then the mouse body 20 is received in the base 10 with asecond orientation (as shown in FIG. 4 ).

When the mouse body 20 is assembled on the base 10 to form a verticalmouse, the user can hold the vertical mouse with the palm of the userplaced standingly (as shown in FIG. 5 and FIG. 6 ), thus reducing thepressure applied to the user's wrist during the operation of thevertical mouse. When the user tends to change the operation mode of thevertical mouse, the user can change the orientation of the mouse body 20with respect to the base 10 to allow the mouse body 20 to be detachedfrom the vertical receiving groove 112 of the base 10. Next, the mousebody 20 is rotated to have a different orientation (for example, themouse body 20 is rotated from the orientation shown in FIG. 3 to theorientation shown in FIG. 4 ). Then, the mouse body 20 is received inthe vertical receiving groove 112 of the base 10. Hence, the mouse body20 can be received in the vertical receiving groove 112 with differentorientations to provide different operation modes.

With reference to FIG. 7 and FIG. 8 . In some embodiments, the housing21 of the mouse body 20 has a back surface 211 and a side surface 213.The side surface 213 is arranged along a profile of the back surface211, and the back surface 211 and the side surface 213 respectively leanagainst the vertical receiving groove 112. In these embodiments, thebase 10 further comprises a first communication unit 13, a position ofthe first communication unit 13 corresponds to a position of thevertical receiving groove 112, the mouse body 20 further comprises asecond communication unit 22, and a position of the second communicationunit 22 corresponds to a position of the back surface 211, so that thesecond communication unit 22 and the first communication unit 13 arecommunicatively connected to each other.

As shown in FIG. 3 , in some embodiments, the back surface 211 of themouse body 20 has a centrosymmetric shape (as shown in FIG. 3 and FIG. 4), but the instant disclosure is not limited thereto. In the case thatthe back surface 211 of the mouse body does not have a centrosymmetricshape, a profile of the vertical receiving groove 112 of the base 10comprises a combination of a profile of the back surface 211 of themouse body 20 before rotation and a profile of the back surface 211 ofthe mouse body 20 after rotation.

In some embodiments where the back surface 211 of the mouse body 20 hasa centrosymmetric shape, the back surface 211 is symmetrically arrangedalong a first symmetry axis X1 and is symmetrically arranged along asecond symmetry axis X2 perpendicular to the first symmetry axis X1, andthe first symmetry axis X1 and the second symmetry axis X2 areintersected at a symmetry center O. In these embodiments, the profile ofthe back surface 211 overlaps the profile of the back surface 211 beingrotated by 180 degrees about the symmetry center O, the symmetry centerO is at a central position of the first symmetry axis X1, and thesymmetry center O is also at a central position of the second symmetryaxis X2.

With reference to FIG. 7 and FIG. 8 . In some embodiments, the case 11of the base 10 has an outer surface and an inner surface opposite to theouter surface. The inner surface is enclosed to form a receiving space,and the outer surface has a bottom surface 111 and the verticalreceiving groove 112. The bottom surface 111 is a flat surface and isconfigured to allow the base 10 to be placed on an operating surface(for example, the surface of a desk) for the operation of the verticalmouse. The vertical receiving groove 112 is opposite to the operatingsurface, and the vertical receiving groove 112 is vertically configured,so that the mouse body 20 can be received in the base 10.

With reference to FIG. 7 and FIG. 8 . In some embodiments, the verticalreceiving groove 112 has a first leaning surface 1121 and a secondleaning surface 1122 connected to the first leaning surface 1121. Anangle θ is between an extension direction of the first leaning surface1121 and the bottom surface 111 of the case 11. When the mouse body 20is received in the vertical receiving groove 112, the back surface 211of the mouse body 20 is attached to the first leaning surface 1121, sothat the mouse body 20 is arranged in a standing configuration which isarranged slantingly with respect to the bottom surface 111. In theseembodiments, when the mouse body 20 is received in the verticalreceiving groove 112 in the standing configuration, the side surface 213of the mouse body 20 is also attached to the second leaning surface1122, so that both the back surface 211 and the side surface 213 of themouse body 20 lean against the vertical receiving groove 112. Therefore,the stability of the mouse body 20 in the standing configuration can beenhanced.

With reference to FIG. 8 . In some embodiments, the angle θ is in arange between 50 degrees and 70 degrees to allow the user's palm to holdthe vertical mouse closely. Alternatively, in some embodiments, theangle θ may be in a range between 55 degrees and 65 degrees to allow theuser's palm to hold the vertical mouse comfortably. Alternatively, insome embodiments, the angle θ may be 55 degrees, 57 degrees, 60 degrees,or the like.

In some embodiments, to increase the stability upon assembling the mousebody 20 on the base 10 and the stability for holding the vertical mousewith the user's palm, the base 10 has a top portion 10 a, the topportion 10 a is on the first leaning surface 1121, the symmetry center Oof the mouse body 20 is correspondingly in the vertical receiving groove112 of the base 10 (that is, as shown in FIG. 3 , the top portion 10 aof the base 10 exceeds a half of the length of the mouse body 20, thetop portion 10 a is higher than the symmetry center O, a portion of theback surface 211 of the mouse body 20 is about two-third of the area ofthe back surface, and the portion of the back surface 211 leans againstthe inner wall of the vertical receiving groove 112), and the center ofgravity of the mouse body 20 is substantially at a central position ofthe entire vertical mouse, but the instant disclosure is not limitedthereto. In some embodiments, the symmetry center O of the mouse body 20is correspondingly on the top portion 10 a of the base 10 (the topportion 10 a of the base 10 corresponds to the half of the length of themouse body 20).

With reference to FIG. 3 . In some embodiments, the mouse body 20 is anelongated body with two curved ends. Therefore, a length of the firstsymmetry axis X1 and a length of the second symmetry axis X2 aredifferent from each other. In these embodiments, the length of the firstsymmetry axis X1 is greater than the length of the second symmetry axisX2, so that the profile of the mouse body 20 is adapted to allow theuser's palm to hold properly.

In some embodiments, under the first operation mode, the mouse body 20is received in the base 10 with the first orientation (as shown in FIG.3 ); under the second operation mode, the mouse body 20 is received inthe base 10 with the second orientation (as shown in FIG. 4 ).Therefore, according to one or some embodiments of the instantdisclosure, the user can hold the vertical mouse standingly, and theoperation mode of the vertical mouse can be switched between the firstoperation mode and the second operation mode according to different userrequirements. Therefore, the adaptability of the operation of thevertical mouse can be enhanced.

In some embodiments, the first operation mode is an operation modesuitable for right-handed users to operate the vertical mouse (as shownin FIG. 5 ), and the second operation mode is an operation mode suitablefor left-handed users to operate the vertical mouse (as shown in FIG. 6). Therefore, the user just needs to rotate the base 10 and the mousebody 20 from 0 degree to 180 degrees respectively to allow the verticalmouse to be suitable for right-handed users or left-handed users.Therefore, according to some embodiments, the same vertical mouse issuitable for both the right-handed users and left-handed users, and thevertical mouse thus provides a great convenience for the users.

With reference to FIG. 7 . In some embodiments, the mouse body 20further comprises an operating structure 23, the housing 21 of the mousebody 20 has a front surface 212 opposite to the back surface 211, andthe back surface 211 and the front surface 212 are respectivelyconnected to two ends of the side surface 213. In these embodiments, themouse body 20 is a two-button mouse. Specifically, in these embodiments,the operating structure 23 comprises two operating buttons 231 and awheel 232, the operating buttons 231 and the wheel 232 are disposed onthe front surface 212 and at one end of the first symmetry axis X1 (asshown in FIG. 3 ), and the wheel 232 is between the two operatingbuttons 231. In these embodiments, the back surface 211, the frontsurface 212, and the side surface 213 of the mouse body 20 are enclosedto form the receiving space for receiving the second communication unit22, but the instant disclosure is not limited thereto.

In some embodiments, for the configuration where the user operates themouse right-handed (as shown in FIG. 3 and FIG. 5 ), the user's rightindex finger presses the left button of the mouse for controlling aprimary button of the mouse, and the user's right middle finger pressesthe right button of the mouse for controlling a secondary button of themouse. In some embodiments where the first operation mode is aright-handed operation mode and the second operation mode is aleft-handed operation mode (as shown in FIG. 4 and FIG. 6 ), theoperation of the vertical mouse under the first operation mode is thesame as the operation of a mouse known to the inventor. However, whenthe orientation of the mouse body 20 is changed from the firstorientation to the second orientation, and the operation mode of themouse body 20 is changed to the second operation mode to allow theuser's left hand to operate the vertical mouse, the operating button 231pressed by the user's left index finger is the secondary button (theright button of the mouse) under the first operation mode.

In some embodiments, when the user operates the vertical mouse by theuser's right hand (as shown in FIG. 3 and FIG. 5 ), the bottom surface111 of the base 10 of the vertical mouse is attached to the operatingsurface (for example, the surface of a desk), the vertical receivinggroove 112 faces the right part of the user and receives mouse body 20,the back surface 211 and the side surface 213 of the mouse body 20 areattached to the vertical receiving groove 112, and the front surface 212faces the right side of the base 10. Under this situation, the user'sright palm is standingly placed on the operating surface; that is, theuser's right little finger is attached to the operating surface, and theuser's palm is away from the operating surface, so that the user's palmis in a standing configuration and not parallel to the operatingsurface. Therefore, under this situation, the user's right index fingerand middle finger correspond to the operating buttons 231 of the mousebody 20, and the user's thumb can hold a side of the base 10 differentfrom a side at which the vertical receiving groove 112 is. Hence, duringthe operations, the user's forearm does not need to be twisted by 90degrees, and the user operates the vertical mouse by a gesture like thatthe user just naturally hangs down the hand on the operating surface, sothat the pressure applied on the user's wrist can be reduced, therebyreducing the muscle strain of the user who operates the mouse for longperiods of time.

In some embodiments, when the user operates the vertical mouse by theuser's left hand (as shown in FIG. 4 and FIG. 6 ), firstly, the base 10is moved to an orientation symmetrical to the original orientation ofthe base 10; that is, the base 10 is rotated by 180 degrees about theuser, so that the vertical receiving groove 112 of the base 10 isrotated from facing right to facing left. Under this configuration, theoperating button 231 of the mouse body 20 is also changed from facingfront to facing back (not shown). Next, the mouse body 20 is completelydetached from the base 10 and is rotated by 180 degrees about thesymmetry center O, so that the operating button 231 of the mouse body 20is also changed from facing back to facing front, thereby allowing thevertical mouse to be under a left-handed operation mode. It is notedthat, in the foregoing embodiments, the base 10 and the mouse body 20are together rotated by 180 degrees and then the mouse body 20 isrotated alone, but the instant disclosure is not limited thereto.Alternatively, in some embodiments, the base 10 and the mouse body 20are firstly completely detached from each other and respectively rotatedby 180 degrees, and then the base 10 and the mouse body 20 are assembledwith each other again, so that the operation mode of the vertical mousecan be switched. Under this configuration, the user's left palm isstandingly placed on the operating surface to operate the verticalmouse; that is, the user's left index finger and middle fingercorrespond to the operating buttons 231 of the mouse body 20, and theuser's thumb holds the base 10.

In some embodiments, the shape of the mouse body 20 corresponds to theshape of the vertical receiving groove 112 of the base 10. The shape ofthe mouse body 20 and the shape of the vertical receiving groove 112 ofthe base 10 may be adjusted to have a plurality of orientations forpositioning according to different user requirements. For example, as tothe different orientations of the mouse body 20, the mouse body 20 inthe vertical receiving groove 112 may be rotated from the original zerodegree (the first operation mode shown in FIG. 3 and FIGS. 5 ) to 180degrees (the second operation mode shown in FIG. 4 and FIG. 6 ), but theinstant disclosure is not limited thereto. In some embodiments, as tothe different orientations of the mouse body 20, the mouse body 20 inthe vertical receiving groove 112 may be rotated from the original 10degrees (the first operation mode) to 170 degrees (the second operationmode), but the instant disclosure is not limited thereto. In someembodiments, as to the different orientations of the mouse body 20, themouse body 20 in the vertical receiving groove 112 may be rotated fromthe original 30 degrees (the first operation mode) to 150 degrees (thesecond operation mode), but the instant disclosure is not limitedthereto. It is noted that, the first operation mode and the secondoperation mode are not limited thereto, and the vertical mouse may haveseveral operation modes. With reference to FIG. 2 to FIG. 9 . In someembodiments, the base 10 further comprises a first sensing module S1.The first sensing module S1 is disposed in the receiving space of thecase 11 and partially exposed from the bottom surface 111 to detect amovement of the base 10. In some embodiments, the vertical mouse may bea mechanical mouse, an optical mouse, or a laser mouse, and the firstsensing module S1 is correspondingly a wheel, an optical sensor, or alaser sensor according to the type of the vertical mouse.

The vertical mouse according to a first embodiment of the instantdisclosure is illustrated below accompanied with FIG. 1 , FIG. 2 , andFIG. 9 . In this embodiment, the connection between the base 10 and themouse body 20 of the vertical mouse and the electronic device isdescribed as below. The vertical mouse is a wired mouse and iscommunicatively connected to the electronic device through a wiredlyconnection, and the mouse body 20 is communicatively connected to thebase 10 in a contact type manner.

With reference to FIG. 9 and FIG. 10 . In some embodiments, the base 10of the vertical mouse comprises an electrical connection cable 17. Oneof two ends of the electrical connection cable 17 is connected to thebottom surface 111 of the base 10, and the other end of the electricalconnection cable 17 is connected to a connection port of the electronicdevice (such as a computer). Hence, the vertical mouse transmitsinformation to the electronic device through the electrical connectioncable 17 and obtains electricity from the electronic device through theelectrical connection cable 17.

With reference to FIG. 1 and FIG. 2 . In these embodiments, the firstcommunication unit 13 and the second communication unit 22 arecommunicatively connected to each other in a contact type manner. Inthese embodiments, the first communication unit 13 of the base 10further comprises a first connector 131, and the second communicationunit 22 of the mouse body 20 comprises a second connector 221. The firstconnector 131 is exposed from the first leaning surface 1121 of thevertical receiving groove 112, and the second connector 221 is exposedfrom the back surface 211 of the housing 21 of the mouse body 20. Whenthe mouse body 20 is received in the vertical receiving groove 112, thefirst connector 131 abuts against the second connector 221, so that thefirst communication unit 13 and the second communication unit 22 arecommunicatively connected to each other.

With reference to FIG. 1 and FIG. 2 . In some embodiments, the base 10is wiredly communicatively connected to the electronic device throughthe electrical connection cable 17, and the base 10 is connected to thesecond connector 221 of the second communication unit 22 of the mousebody 20 through the first connector 131 of the first communication unit13, so that the base 10 and the mouse body 20 are communicativelyconnected to each other. In this embodiment, the user assembles themouse body 20 on the base 10. When the user assembles the mouse body 20on the base 10 to operate the vertical mouse to move, the first sensingmodule S1 of the base 10 transmits a movement signal to the electronicdevice through the electrical connection cable 17 to correspond to themovement of the cursor. When the user operates the vertical mouse andcontrols the operating structure 23 of the mouse body 20, the operatingstructure 23 generates a control signal, and the control signal istransmitted to the first connector 131 of a microcontroller unit (MCU)(not shown) of a circuit board in the base 10 through the secondconnector 221 of the second communication unit 22. After the firstconnector 131 receives the control signal, the control signal of themouse body 20 is transmitted to the electronic device through theelectrical connection cable 17 between the base 10 and the electronicdevice to control the electronic device.

With reference to FIG. 1 . In some embodiments, the first connector 131may be a pogo pin connector or other types of connectors (e.g., a bladepin connector), and the second connector 221 is a conductive contactcorresponding to the pogo pin connector to achieve the communicationconnection between the first connector 131 and the second connector 211,but the instant disclosure is not limited thereto.

With reference to FIG. 1 and FIG. 2 . In some embodiments, to meet theuser's operation preferences, the vertical mouse further comprises aswitching module 24. The switching module 24 is communicativelyconnected to the operating structure 23 to switch functions of theoperating structure 23. The switching module 24 may be disposed on thebase 10 or the mouse body 20, but the instant disclosure is not limitedthereto.

With reference to FIG. 1 and FIG. 2 . In some embodiments, the functionsof the operating buttons 231 are automatically switched through thedetection of the change of the orientation of the mouse body 20. In thisembodiment, the base 10 comprises two sensing portions 14, and theswitching module 24 is disposed on the mouse body 20 and comprises aswitching circuit 241 and a sensor 243.

With reference to FIG. 1 and FIG. 2 . In these embodiments, the twosensing portions 14 of the base 10 are disposed in the verticalreceiving groove 112, the switching circuit 241 and the sensor 243 aredisposed in the housing 21 of the mouse body 20, and the sensor 243 isat one side of the second symmetry axis X2 and electrically connected tothe switching circuit 241. Under the first operation mode, a position ofthe sensor 243 corresponds to a position of one of the two sensingportions 14; under the second operation mode, the position of the sensor243 corresponds to a position of the other sensing portion 14. When thesensing portion 243 sensed by the sensor 14 is changed, the switchingcircuit 241 switches the functions of the operating buttons 231. In thisembodiment, the sensor 243 may be a bipolar Hall sensor, and the twosensing portions 14 on the base 10 are magnets with opposite polarities.Under this configuration, when the orientation of the mouse body 20 ischanged, the sensor 243 can determine the orientation of the mouse body20 through the sensing of the magnets with different polarities. It isnoted that, the implementation of the sensor 243 is not limited thereto.In some embodiments, the switching module 24 may be disposed in the base10, and the sensing portions 14 are disposed on the mouse body 20, sothat the purpose of automatically switching the functions of theoperating buttons 231 can also be achieved.

In some embodiments, the sensor 243 may be a G-sensor. The sensor 243 inthe mouse body 20 detects that the mouse body 20 is flipped from thefirst operation mode to the second operation mode or detects the changeof the axial acceleration when the mouse body 20 is placed on the desk.The X axis, the Y axis, and the Z axis of the sensor 243 with respect tothe center of earth are utilized to obtain three angles, themicrocontroller unit (MCU) of the circuit board in the mouse body 20determines whether the mouse body 20 is under the first operation mode,the second operation mode, or operating alone on an operating surface(e.g., the surface of the desk) according to the changes of theaccelerations of the sensor 243 along the X axis, the Y axis, and the Zaxis (according to whether the angles are within a certain range).Therefore, the operation mode of the mouse body 20 can be determined andthe possibility of signal misjudgment can be reduced.

With reference to FIG. 1 . In some embodiments, the base 10 furthercomprises a first magnetic attractive member 16, and the mouse body 20further comprises a second magnetic attractive member 28 and a thirdmagnetic attractive member 29. When the mouse body 20 is received in thevertical receiving groove 112 with the first orientation, the firstmagnetic attractive member 16 is magnetically attracted to the secondmagnetic attractive member 28; when the mouse body 20 is received in thevertical receiving groove 112 with respect to the second orientation,the first magnetic attractive member 16 is magnetically attracted to thethird magnetic attractive member 29.

With reference to FIG. 1 . In these embodiments, the number of the firstmagnetic attractive members 16 of the base 10 is two, and the two firstmagnetic attractive members 16 are disposed on one side of the firstleaning surface 1121 adjacent to the bottom surface 111; the number ofthe second magnetic attractive members 28 and the number of the thirdmagnetic attractive members 29 of the mouse body 20 are respectivelytwo. In this embodiment, the two second magnetic attractive members 28and the two third magnetic attractive members 29 are symmetricallyarranged with respect to the first symmetry axis X1, the two secondmagnetic attractive members 28 are symmetrically arranged with eachother with respect to the second symmetry axis X2, and the two thirdmagnetic attractive members 29 are symmetrically arranged with eachother with respect to the second symmetry axis X2. Therefore, no matterthe mouse body 20 is received in the vertical receiving groove 112 withthe first orientation or the second orientation, the mouse body 20 canbe positioned with the base 10 through the magnetic attraction betweenthe magnetic attractive members. Hence, the stability for positioningthe mouse body 20 with the base 10 can be enhanced.

With reference to FIG. 1 and FIG. 2 . In some embodiments where thefirst communication unit 13 and the second communication unit 22 arecommunicatively connected to each other in a contact type manner, toensure that the mouse body 20 can be properly abut against the base 10after the mouse body 20 is received in the vertical receiving groove112, the base 10 comprises a first guiding structure 15, and the mousebody 20 comprises a second guiding structure 27. The first guidingstructure 15 is disposed on the first leaning surface 1121 of thevertical receiving groove 112, and the second guiding structure 27 isdisposed on the back surface 211 of the housing 21 of the mouse body 20.When the mouse body 20 is received in the vertical receiving groove 112of the base 10, and the first guiding structure 15 corresponds to thesecond guiding structure 27, the first connector 131 properly abutsagainst the second connector 221. Hence, the convenience of the verticalmouse during operation can be enhanced.

With reference to FIG. 1 . In some embodiments, the first guidingstructure 15 may be a post structure, and the second guiding structure27 may be a groove structure capable of being fitted over the poststructure, but the instant disclosure is not limited thereto. It isnoted that, in these embodiments, the first guiding structure 15 and thesecond guiding structure 27 can guide the mouse body 20 to be assembledin the vertical receiving groove 112 of the base 10, so that the firstconnector 131 and the second connector 221 are communicatively connectedto each other in a contact type manner. Furthermore, the mating betweenthe convex structure and the concave structure of the first guidingstructure 15 and the second guiding structure 27 allow the mouse body 20and the base 10 to be positioned with each other. Hence, the stabilityof the vertical mouse during operation can be enhanced.

With reference to FIG. 1 . In some embodiments where the firstcommunication unit 13 and the second communication unit 22 arecommunicatively connected to each other in a contact type manner, toensure that the mouse body 20 can be properly abut against the base 10after the mouse body 20 is received in the vertical receiving groove112, the base 10 comprises a first magnetic attractive member 16 and afirst guiding structure 15, and the mouse body 20 comprises a secondmagnetic attractive member 28, a third magnetic attractive member 29,and a second guiding structure 27. Therefore, the base 10 and the mousebody 20 not only can be positioned with each other through the magneticattraction but also can be guided with each other through the matingbetween the convex structure and the concave structure of the firstguiding structure 15 and the second guiding structure 27. Hence, thestability of the vertical mouse during operation can be enhanced.

With reference to FIG. 1 , FIG. 2 , FIG. 9 , and FIG. 10 . In someembodiments where the base 10 is wiredly communicatively connected tothe electronic device through the electrical connection cable 17, themouse body 20 does not have the power unit, and the mouse body 20 isdisposed on the base 10 for operation.

With reference to FIG. 9 and FIG. 10 . In some embodiments, the base 10further comprises a slit 113, the slit 113 is on the bottom surface 111of the case 11 of the base 10, and the slit 113 is defined through twoends of the bottom surface 11. In these embodiments, the electricalconnection cable 17 is communicatively connected to the first sensingmodule S1 and the first communication unit 13 of the base 10, and theelectrical connection cable 17 protrudes out of the bottom surface 111of the case 11 of the base 10. Specifically, in this embodiment, alocation where the electrical connection cable 17 protrudes out of thebottom surface 111 of the case 11 of the base 10 is between two ends ofthe slit 113. Therefore, when the user flips the base 10 to operate thevertical mouse 10 with different operation modes, the electricalconnection cable 17 can be received at different portions of the slit113 so as to be protruded out of the base 10 with different directions,thus facilitating user's operation.

With reference to FIG. 8 . In some embodiments, the first communicationunit 13 is disposed on the case 11, and the position of the firstcommunication unit 13 corresponds to the position of the verticalreceiving groove 112. Therefore, when the mouse body 20 is received inthe vertical receiving groove 112, the base 10 can be communicativelyconnected to the mouse body 20. Specifically, the first communicationunit 13 is not limited to be disposed in or out of the receiving spaceof the case 11. In some embodiments, the first communication unit 13 isa noncontact type communication unit and disposed in the receiving spaceof the case 11.

The vertical mouse according to a second embodiment of the instantdisclosure is illustrated below accompanied with FIG. 7 to FIG. 12 . Thedifference between the first embodiment and the second embodiment is atleast that, in the second embodiment, the mouse body 20 iscommunicatively connected to the base 10 in a noncontact type manner. Inthis embodiment, descriptions about the configuration of the base 10 ofthe vertical mouse and the connection and communication between the base10 and the electronic device can be referred to the descriptions of thefirst embodiment and are not repeated here.

With reference to FIG. 8 , FIG. 11 , and FIG. 12 . In some embodiments,the first communication unit 13 of the base 10 and the secondcommunication unit 22 of the mouse body 20 are corresponding noncontacttype communication structures. In these embodiments, the firstcommunication unit 13 is a near field communication (NFC) reader, andthe second communication unit 22 is an NFC tag having a coil module.Therefore, as long as the mouse body 20 is received in the verticalreceiving groove 112 of the base 10, the communicational connectionbetween the base 10 and the mouse body 20 can be achieved. Therefore,the base 10 can retrieve the operation of the user on the mouse body 20,so that the operation of the mouse body 20 is correspondingly presentedon the electronic device.

With reference to FIG. 8 to FIG. 12 . In some embodiments, the base 10is communicatively connected to the electronic device through theelectrical connection cable 17 (as shown in FIG. 9 and FIG. 10 ), andthe base 10 is communicatively connected to the second communicationunit 22 of the mouse body 20 through the first communication unit 13 ina noncontact type manner. In this embodiment, the user assembles themouse body 20 on the base 10. When the user assembles the mouse body 20on the base 10 to operate the vertical mouse to move, the first sensingmodule Si (as shown in FIG. 9 and FIG. 10 ) of the base 10 transmits amovement signal to the electronic device through the electricalconnection cable 17 to correspond to the movement of the cursor. Whenthe user operates the vertical mouse and controls the operatingstructure 23 of the mouse body 20, the operating structure 23 generatesa control signal, and the control signal is transmitted to the firstcommunication unit 13 of the base 10 through the second communicationunit 22 of a microcontroller unit (MCU) (not shown) of a circuit boardin the mouse body 20. After the first communication unit 13 receives thecontrol signal, the control signal of the mouse body 20 is transmittedto the electronic device through the electrical connection cable 17between the base 10 and the electronic device to control the electronicdevice.

With reference to FIG. 8 , FIG. 11 , and FIG. 12 . In some embodiments,the mouse body 20 further comprises a second wireless communication unit26 and a second sensing module S2, and the second wireless communicationunit 26 is disposed in the housing 21 of the mouse body 20 and partiallyexposed from the back surface 211 to detect the movement of the mousebody 20. In these embodiments, the mouse body 20 can be detached fromthe base 10 and is operated alone. When the bottom surface of the mousebody 20 is placed and moving on the operating surface (e.g., the surfaceof a desk), the second sensing module S2 of the mouse body 20 generatesa movement signal and the movement signal is transmitted to theelectronic device through the second wireless communication unit 26 ofthe microcontroller unit (MCU) of the circuit board in the mouse body 20to control the movement of the cursor. When the user operates the mousebody 20 alone and controls the operating structure 23 of the mouse body20, the operating structure 23 generates a control signal, and thesecond wireless communication unit 26 transmits the control signal tothe electronic device to control the electronic device. In someembodiments, the second wireless communication unit 26 is a Bluetoothcommunication unit or a radiofrequency (RF) communication unit, but theinstant disclosure is not limited thereto.

With reference to FIG. 11 and FIG. 12 . In some embodiments, theswitching module 24 of the mouse body 20 comprises a switching circuit241 and a switching structure 242. The switching circuit 241 is disposedin the housing 21 of the mouse body 20 and is communicatively connectedto the switching structure 242 and the operating buttons 231, and theswitching structure 242 is disposed on the back surface 211 of thehousing 21. Specifically, in some embodiments, the switching structure242 may be a toggle. The switching circuit 241 is triggered by changingthe position of the switching structure 242, and the switching circuit241 can switch the functions of the operating buttons 231 through thetriggering of the switching structure 242, but the instant disclosure isnot limited thereto. In these embodiments, the switching module 24 isnot limited to be manually switched and may also comprise, same as thefirst embodiment, the switching circuit 241 and the sensor 243 (as shownin FIG. 1 and FIG. 2 ). In this embodiment, the functions of theoperating buttons 231 are automatically switched through the detectionof the change of the orientation of the mouse body 20. The configurationand the operation of the switching module 24 can be referred to thedescriptions of the first embodiment and are not repeated here.

With reference to FIG. 11 . In some embodiments, the vertical receivinggroove 112 of the base 10 further comprises a first positioning portion1123, and the housing 21 of the mouse body 20 further comprises a secondpositioning portion 214. When the mouse body 20 is received in thevertical receiving groove 112 of the base 10, the mouse body 20 ispositioned with the first positioning portion 1123 of the verticalreceiving groove 1112 through the second positioning portion 214.Therefore, the stability for assembling the mouse body 20 on the base 10can be enhanced. In these embodiments, the first positioning portion1123 is an L-shaped block, the second positioning portion 214 is a slot,and the mouse body 20 is slidably fitted over the first positioningportion 1123 in the L-shaped block configuration through the secondpositioning portion 214 in the slot configuration, but the instantdisclosure is not limited thereto.

With reference to FIG. 7 to FIG. 12 . In these embodiments, the base 10is wiredly communicatively connected to the electronic device throughthe electrical connection cable 17. The mouse body 20 further comprisesa power unit 25, and the power unit 25 and the second wirelesscommunication unit 26 are electrically connected to each other and arerespectively disposed in the housing 21 of the mouse body 20. In thisembodiment, the mouse body 20 may be detached from the base 10 andturned to be powered by the power unit 25, and the second wirelesscommunication unit 26 is communicatively connected to the electronicdevice, so that the mouse body 20 alone can be served as a common mouse.It is noted that, in some embodiments where the mouse body 20 can bedetached from the base 10, the mouse body 20 is connected to the mainssupply through the electrical connection cable 17, so that theelectricity for the mouse body 20 can be provided by the mains supply;the power unit 25 may be a rechargeable battery, but the instantdisclosure is not limited thereto.

Moreover, the electrical connection cable 17 of the vertical mouse maybe pluggable, one of two ends of the electrical connection cable 17 ispluggable connected to the base 10, and the other end of the electricalconnection cable 17 is connected to the connection port of theelectronic device. Hence, the vertical mouse transmits information tothe electronic device through the electrical connection cable 17 andobtains electricity from the electronic device through the electricalconnection cable 17. In these embodiments, a rechargeable power unit 25is disposed in the base 10. Therefore, the vertical mouse can beconnected to the connection port of the electronic device through thepluggable electrical connection cable 17, and the vertical mouse iscommunicatively connected to the electronic device through the pluggableelectrical connection cable 17. Hence, the rechargeable power unit 25can be charged, and thus the electricity for operating the wirelessvertical mouse can be provided.

The vertical mouse according to a third embodiment of the instantdisclosure is illustrated below accompanied with FIG. 7 , FIG. 10 , FIG.11 , and FIG. 13 . The difference between the second embodiment and thethird embodiment is at least that, in the third embodiment, the verticalmouse is wiredly communicatively connected to an external device capableof supplying electricity, and the mouse body 20 is, same as the secondembodiment, wirelessly communicatively connected to the electronicdevice. In this embodiment, the descriptions about the wirelesslycommunication connection between the mouse body 20 and the electronicdevice can be referred to the descriptions of the second embodiment andare not repeated here. The base 10 of the vertical mouse is connected toconnection port of the external device (a device capable of supplyingelectricity and other than a computer) through the electrical connectioncable 17, and the vertical mouse obtains the electricity from theexternal device through the electrical connection cable 17.

With reference to FIG. 13 . In this embodiment, when the user assemblesthe mouse body 20 on the base 10 to operate the vertical mouse to move,the first sensing module S1 of the base 10 transmits a movement signalto the second communication unit 22 of the mouse body 20 through thefirst communication unit 13, and the movement signal is transmitted tothe electronic device through the second wireless communication unit 26of a microcontroller unit (MCU) of a circuit board in the mouse body 20to control the movement of the cursor. When the user assembles the mousebody 20 on the base 10 and controls the operating structure 23 of themouse body 20, the operating structure 23 generates a control signal,and the control signal is transmitted to the electronic device throughthe second wireless communication unit 26 of the microcontroller unit(MCU) of a circuit board in the mouse body 20 to control the electronicdevice.

The vertical mouse according to a fourth embodiment of the instantdisclosure is illustrated below accompanied with FIG. 14 . Thedifference between the second embodiment and the fourth embodiment is atleast that, in the fourth embodiment, the base 10 of the vertical mousefurther comprises a first wireless communication unit 18, and the base10 of the vertical mouse is wirelessly communicatively connected to theelectronic device through the first wireless communication unit 18.

With reference to FIG. 14 . In these embodiments, the user may assemblethe mouse body 20 on the base 10 for operation or may detach the mousebody 20 from the base 10 and operates the mouse body 20 alone. When theuser assembles the mouse body 20 on the base 10 to operate the verticalmouse to move, the first sensing module S1 of the base 10 transmits amovement signal to the electronic device through the first wirelesscommunication unit 18 to correspond to the movement of cursor. When theuser assembles the mouse body 20 on the base 10 and controls theoperating structure 23 of the mouse body 20, the operating structure 23generates a control signal, the control signal is transmitted to thefirst communication unit 13 of a microcontroller unit (MCU) of a circuitin the base 10 through the second communication unit 22, and the firstcommunication unit 13 receives the control signal and the control signalof the mouse body 20 is transmitted to the electronic device through thefirst wireless communication unit 18 to control the electronic device.

With reference to FIG. 14 . In some embodiments, because the mouse body20 comprises the second wireless communication unit 26, when the userassembles the mouse body 20 on the base 10 to operate the vertical mouseto move or to control the operating structure 23 of the mouse body 20,the mouse body 20, same as the third embodiment, can directly transmitthe movement signal or the control signal of the operating structure 23of the mouse body 20 to the electronic device through the secondwireless communication unit 26.

Based on the above, according to some embodiments, the user can placethe vertical mouse on an operating surface and operates the verticalmouse, with the palm of the user placed standingly, thus reducing thepressure applied to the user's wrist during the operation of thevertical mouse. Moreover, according to some embodiments, the user justneeds to rotate the base and the mouse body respectively to allow thevertical mouse to be suitable for right-handed users or left-handedusers. Therefore, according to some embodiments, the same vertical mouseis suitable for both the right-handed users and left-handed users, andthe vertical mouse thus provides a great convenience for the users.

While the instant disclosure has been described by the way of exampleand in terms of the preferred embodiments, it is to be understood thatthe invention need not be limited to the disclosed embodiments. On thecontrary, it is intended to cover various modifications and similararrangements included within the spirit and scope of the appendedclaims, the scope of which should be accorded the broadestinterpretation so as to encompass all such modifications and similarstructures.

What is claimed is:
 1. A vertical mouse comprising: a base having avertical receiving groove; and a mouse body comprising a housing,wherein the mouse body is detachably received in the vertical receivinggroove, the housing leans against the vertical receiving groove, and themouse body has a first operation mode and a second operation mode; underthe first operation mode, the mouse body is received in the base with afirst orientation, and under the second operation mode, the mouse bodyis received in the base with a second orientation.
 2. The vertical mouseaccording to claim 1, wherein a back surface of the housing of the mousebody is symmetrically arranged along a first symmetry axis and issymmetrically arranged along a second symmetry axis perpendicular to thefirst symmetry axis, a side surface of the housing is arranged along aprofile of the back surface, and the back surface and the side surfacerespectively lean against the vertical receiving groove.
 3. The verticalmouse according to claim 2, wherein the first symmetry axis and thesecond symmetry axis are intersected at a symmetry center, the mousebody is selectively received in the vertical receiving groove with oneof a plurality of orientations, and the mouse body is rotated about thesymmetry center, so that the mouse body is arranged with multipleorientations.
 4. The vertical mouse according to claim 1, wherein thevertical receiving groove of the base further has a first positioningportion, a back surface of the mouse body further has a secondpositioning portion, and the mouse body is slidably fitted over thefirst positioning portion through the second positioning portion.
 5. Thevertical mouse according to claim 1, wherein the base further comprisesa first magnetic attractive member, and the mouse body further comprisesa second magnetic attractive member and a third magnetic attractivemember; when the mouse body is received in the vertical receiving groovewith the first orientation, the first magnetic attractive member ismagnetically attracted to the second magnetic attractive member; whenthe mouse body is received in the vertical receiving groove with thesecond orientation, the first magnetic attractive member is magneticallyattracted to the third magnetic attractive member.
 6. The vertical mouseaccording to claim 5, wherein a back surface of the housing of the mousebody is arranged along a first symmetry axis, and the third magneticattractive member and the second magnetic attractive member are atopposite sides with respect to the first symmetry axis.
 7. The verticalmouse according to claim 3, wherein the symmetry center of the mousebody is correspondingly in the vertical receiving groove of the base. 8.The vertical mouse according to claim 1, wherein the vertical receivinggroove has a first leaning surface, an angle is between an extensiondirection of the first leaning surface and a bottom surface of the base,and a back surface of the mouse body is attached to the first leaningsurface.
 9. The vertical mouse according to claim 8, wherein the angleis in a range between 50 degrees and 70 degrees.
 10. A vertical mouseadapted to be utilized along with an electronic device, wherein thevertical mouse comprises: a base communicatively connected to theelectronic device, wherein the base comprises a first sensing module anda first communication unit, and the first sensing module is configuredto detect a movement of the base; a mouse body comprising an operatingstructure and a second communication unit, wherein the operatingstructure is configured to control the electronic device, the secondcommunication unit is communicatively connected to the firstcommunication unit, the mouse body is detachably arranged on the base,and the mouse body has a first operation mode and a second operationmode; under the first operation mode, the mouse body is arranged on thebase with a first orientation, and under the second operation mode, themouse body is arranged on the base with a second orientation; and aswitching module communicatively connected to the operating structure,wherein the switching module is configured to switch the operatingstructure to correspond to the first operation mode or the secondoperation mode.
 11. The vertical mouse according to claim 10, whereinwhen the mouse body is arranged on the base and the base is moving, thefirst sensing module of the base generates a movement signal, and thebase transmits the movement signal to the electronic device.
 12. Thevertical mouse according to claim 10, wherein when the mouse body isarranged on the base and controls the operating structure of the mousebody, the operating structure generates a control signal and transmitsthe control signal to the base through the second communication unit,and the base transmits the control signal to the electronic device tocontrol the electronic device.
 13. The vertical mouse according to claim10, wherein the operating structure comprises two operating buttons;when an orientation of the mouse body is changed, the switching moduleswitches functions of the two operating buttons.
 14. The vertical mouseaccording to claim 10, wherein the switching module comprises aswitching circuit and a sensor electrically connected to the switchingcircuit, and the switching circuit detects whether the mouse body isunder the first operation mode or the second operation mode according tothe sensor so as to switch functions of the operating structure.
 15. Thevertical mouse according to claim 14, wherein the base further comprisestwo sensing portions; under the first operation mode, a position of thesensor corresponds to a position of one of the two sensing portions;under the second operation mode, the position of the sensor correspondsto a position of the other sensing portion; when the sensing portionsensed by the sensor is changed, the switching circuit switches thefunction of the operating structure.
 16. The vertical mouse according toclaim 15, wherein the sensor is a Hall sensor, and the sensing portionsare magnets.
 17. The vertical mouse according to claim 14, wherein thesensor is a G-sensor to detect whether the mouse body is under the firstoperation mode, the second operation mode, or operating on an operatingsurface alone.
 18. The vertical mouse according to claim 10, wherein thefirst communication unit and the second communication unit arecommunicatively connected to each other in a contact type manner. 19.The vertical mouse according to claim 18, wherein the firstcommunication unit comprises a first connector, the second communicationunit comprises a second connector, and the first connector contacts thesecond connector, so that the first communication unit and the secondcommunication unit are communicatively connected to each other.
 20. Thevertical mouse according to claim 19, wherein the first connector is apogo pin connector, and the second connector is a conductive contact.21. A vertical mouse adapted to be utilized along with an electronicdevice, wherein the vertical mouse comprises: a base communicativelyconnected to the electronic device, wherein the base comprises a firstsensing module and a first communication unit, and the first sensingmodule is configured to detect a movement of the base; a mouse bodycomprising an operating structure, a second communication unit, and asecond wireless communication unit, wherein the operating structure isconfigured to control the electronic device, the second communicationunit is communicatively connected to the first communication unit, thesecond wireless communication unit is wirelessly communicativelyconnected to the electronic device, the mouse body is detachablyarranged on the base, and the mouse body has a first operation mode anda second operation mode; under the first operation mode, the mouse bodyis arranged on the base with a first orientation, and under the secondoperation mode, the mouse body is arranged on the base with a secondorientation; and a switching module communicatively connected to theoperating structure, wherein the switching module is configured toswitch the operating structure to correspond to the first operation modeor the second operation mode.
 22. The vertical mouse according to claim21, wherein the switching module comprises a switching circuit and aswitching structure electrically connected to the switching circuit, andthe switching circuit switches functions of the operating structureaccording to a triggering of the switching structure.
 23. The verticalmouse according to claim 21, wherein the mouse body comprises a secondsensing module and a power unit, the second sensing module is configuredto detect a movement of the mouse body; when the mouse body is detachedfrom the base and is moving, the second sensing module of the mouse bodygenerates a movement signal, and the second wireless communication unittransmits the movement signal to the electronic device.
 24. The verticalmouse according to claim 21, wherein when the mouse body is detachedfrom the base and controls the operating structure of the mouse body,the operating structure generates a control signal and transmits thecontrol signal to the electronic device through the second wirelesscommunication unit to control the electronic device.
 25. The verticalmouse according to claim 21, wherein the first communication unit andthe second communication unit are corresponding noncontact typecommunication structures.
 26. The vertical mouse according to claim 21,wherein the base further comprises a first wireless communication unit,and the base is wirelessly communicatively connected to the electronicdevice through the first wireless communication unit.
 27. The verticalmouse according to claim 26, wherein when the mouse body is arranged onthe base and the base is moving, the first sensing module of the basegenerates a movement signal, and the first wireless communication unittransmits the movement signal to the electronic device.
 28. The verticalmouse according to claim 26, wherein when the mouse body is arranged onthe base and controls the operating structure of the mouse body, theoperating structure generates a control signal and transmits the controlsignal to the base through the second communication unit, and the basetransmits the control signal to the electronic device through the firstwireless communication unit to control the electronic device.
 29. Avertical mouse adapted to be utilized along with an electronic deviceand an external device, wherein the vertical mouse comprises: a basecommunicatively connected to the external device, wherein the basecomprises a first sensing module and a first communication unit, and thefirst sensing module is configured to detect a movement of the base; amouse body comprising an operating structure, a second communicationunit, and a second wireless communication unit, wherein the operatingstructure is configured to control the electronic device, the secondcommunication unit is communicatively connected to the firstcommunication unit, the second wireless communication unit is wirelesslycommunicatively connected to the electronic device, the mouse body isdetachably arranged on the base, and the mouse body has a firstoperation mode and a second operation mode; under the first operationmode, the mouse body is arranged on the base with a first orientation,and under the second operation mode, the mouse body is arranged on thebase with a second orientation; and a switching module communicativelyconnected to the operating structure, wherein the switching module isconfigured to switch the operating structure to correspond to the firstoperation mode or the second operation mode.
 30. The vertical mouseaccording to claim 29, wherein when the mouse body is arranged on thebase and the base is moving, the first sensing module of the basegenerates a movement signal, the first communication unit transmits themovement signal to the second communication unit of the mouse body, andthe second wireless communication unit of the mouse body transmits themovement signal to the electronic device.
 31. The vertical mouseaccording to claim 29, wherein when the mouse body is arranged on thebase and controls the operating structure of the mouse body, theoperating structure generates a control signal and transmits the controlsignal to the electronic device through the second wirelesscommunication unit to control the electronic device.
 32. The verticalmouse according to claim 29, wherein the switching module comprises aswitching circuit and a sensor electrically connected to the switchingcircuit, and the switching circuit detects whether the mouse body isunder the first operation mode or the second operation mode according tothe sensor so as to switch functions of the operating structure.